According to one embodiment, a liquid crystal display includes a display module and a backlight module configured to irradiate light on the display module. The backlight module includes a light guide plate, a first light source, a reflective plate, and a second light source. The light guide plate has a light output face at a position corresponding to a first small area on the display module. The first light source is configured to irradiate light toward the light guide plate from a side of the light guide plate in such a manner that the irradiated light reaches the first small area. The reflective plate is facing to the light guide plate, and the reflective plate has a reflective face configured to reflect light toward a second small area different from the first small area. The second light source is configured to irradiate light toward the reflective plate from a side of the reflective plate in such a manner that the irradiated light reaches the second small area.
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16. A backlight module comprising:
a light guide plate comprising a light output face at a predetermined position;
a first light source configured to irradiate light toward the light guide plate from a side of the light guide plate, the first light source corresponding to the light output face;
a reflective plate comprising a reflective face configured to reflect light toward a predetermined direction, the reflective face tilting with regard to the light guide plate; and
a second light source configured to irradiate light toward the reflective plate from a side of the reflective plate, the second light source corresponding to the reflective face, the irradiated light reaching the reflective face without passing through the light guide plate.
1. A liquid crystal display comprising:
a display module; and
a backlight module configured to irradiate light on the display module;
wherein the backlight module comprises:
a light guide plate comprising a light output face at a position corresponding to a first small area on the display module;
a first light source configured to irradiate light toward the light guide plate from a side of the light guide plate in such a manner that the irradiated light reaches the first small area;
a reflective plate facing to the light guide plate, the reflective plate comprising a reflective face configured to reflect light toward a second small area different from the first small area, the reflective face tilting with regard to the light guide plate; and
a second light source configured to irradiate light toward the reflective plate from a side of the reflective plate so that the irradiated light reaches the reflective face without passing through the light guide plate, and after being reflected, the irradiated light reaches the second small area.
8. A liquid crystal display comprising:
a display module; and
a backlight module configured to irradiate light on the display module;
wherein the backlight module comprises:
a light guide plate comprising a plurality of light output faces at a plurality of positions each of which corresponds to each of a plurality of first small areas on the display module;
a plurality of first light sources each of which corresponds to each of the first small areas, each of the first light sources being configured to irradiate light toward the light guide plate from a side of the light guide plate in such a manner that the irradiated light reaches each of the first small areas;
a reflective plate facing to the light guide plate, the reflective plate comprising a plurality of reflective faces each of which is configured to reflect light toward each of a plurality of second small areas different from the first small areas, the reflective face tilting with regard to the light guide plate; and
a plurality of second light sources each of which corresponds to each of the second small areas, each of the second light sources is configured to irradiate light toward the reflective plate from a side of the reflective plate so that the irradiated light reaches the reflective face without padding through the light guide plate, and after reflection, the irradiated light reaches each of the second small areas.
2. The display of
a first prism sheet between the light guide plate and the display module arranged at a first place corresponding to the light output face, the first prism being configured to set a proceeding direction of the light take out from the light output face of the light guide plate toward the display module; and
a second prism sheet between the light guide plate and the reflective plate arranged at a second place corresponding to the reflective face, the second prism sheet being configured to set a proceeding direction of the light reflected at the reflective face toward the display module.
3. The display of
4. The display of
5. The display of
7. The display of
an image processing circuit configured to perform image processing on an input video signal;
a panel controller configured to provide the image-processed input video signal to the display module at predetermined timing; and
a backlight controller configured to control the first and the second light sources of the backlight module,
wherein the reflective plate comprises a flat face extending from a top of the reflective face, and
at least a part of the image processing circuit, the panel controller and the backlight controller is arranged under the flat face.
9. The display of
10. The display of
a first prism sheet between the light guide plate and the display module arranged at a first place corresponding to the light output face, the first prism being configured to set a proceeding direction of the light take out from the light output face of the light guide plate toward the display module; and
a second prism sheet between the light guide plate and the reflective plate arranged at a second place corresponding to the reflective face, the second prism sheet being configured to set a proceeding direction of the light reflected at the reflective face toward the display module.
11. The display of
12. The display of
13. The display of
15. The display of
an image processing circuit configured to perform image processing on an input video signal;
a panel controller configured to provide the image-processed input video signal to the display module at predetermined timing; and
a backlight controller configured to control the first and the second light sources of the backlight module,
wherein the reflective plate comprises a flat face extending from a top of the reflective face, and
at least a part of the image processing circuit, the panel controller and the backlight controller is arranged under the flat face.
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This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2010-256145, filed on Nov. 16, 2010, the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a liquid crystal display and a backlight module.
Recently, a liquid crystal display has been widely used. The liquid crystal display has a liquid crystal panel composed by putting liquid crystal materials between a pair of glass substrates and a backlight module for irradiating light on the liquid crystal panel from back side thereof. In order to reduce a manufacturing cost, it is necessary to reduce the cost of not only the liquid crystal panel but also the backlight module.
In general, according to one embodiment, a liquid crystal display includes a display module and a backlight module configured to irradiate light on the display module. The backlight module includes a light guide plate, a first light source, a reflective plate, and a second light source. The light guide plate has a light output face at a position corresponding to a first small area on the display module. The first light source is configured to irradiate light toward the light guide plate from a side of the light guide plate in such a manner that the irradiated light reaches the first small area. The reflective plate is facing to the light guide plate, and the reflective plate has a reflective face configured to reflect light toward a second small area different from the first small area. The second light source is configured to irradiate light toward the reflective plate from a side of the reflective plate in such a manner that the irradiated light reaches the second small area.
Embodiments will now be explained with reference to the accompanying drawings.
(First Embodiment)
The liquid crystal panel 1 has a structure where liquid crystal materials are put between a pair of facing glass substrates. The liquid crystal panel 1 has a plurality of (for example, “1080” of) scanning lines, a plurality of (for example, “1920*3” of) signal lines, and a plurality of liquid crystal pixels formed on each of crossing points of the scanning lines and the signal line.
The image processing circuit 2 performs image processing such as decoding processing or processing for high quality image on an input video signal inputted from the outside. The timing controller 3 provides the image-processed input video signal to the source driver 5 and controls the operation timing of the gate driver 4, source driver 5 and backlight controller 6.
The gate driver 4 selects one of the scanning lines by turns. The source driver 5 provides the input video signal to the signal lines of the liquid crystal panel 1. The input video signal is provided to the liquid crystal pixel connected to the scanning line selected by the gate driver 4. According to the voltage of the supplied input video signal, alignments of the liquid crystal materials in the liquid crystal pixel vary. Here, a panel controller has the gate driver 4 and the source driver 5.
On the other hand, the backlight module 7, whose size is substantially the same as that of the liquid crystal panel 1, is arranged behind the liquid crystal panel 1 to irradiate light thereon. Among the irradiated light, light whose intensity depends on the alignments of the liquid crystal materials, is transmissive to the liquid crystal materials to be displayed on the liquid crystal panel 1.
In the present embodiment, the liquid crystal panel 1 is divided into a plurality of small areas. The backlight controller includes an inverter circuit which controls the backlight module 7 so that the high intensity light is irradiated on the small area where the input video signal of high luminance is displayed and the low intensity light is irradiated on the small area where the input video signal of low luminance is displayed, for example. Because of this, contrast ratio of the displayed image improves.
The light guide plate 12 is, for example, made of acrylic, and a diffusion pattern 12a is formed on the central part corresponding to the first area. Furthermore, as shown in
The light sources 11 are, for example, cold cathode fluorescent lamps or LEDs (Light Emitting Diode). One light source can have three kinds of LEDs which emit red, green and blue lights, respectively. Five light sources 11a0 to 11a4 are arranged at the left side of the light guide plate 12 for irradiating the five small areas A0 to A4, respectively, while five light sources 11a5 to 11a9 are arranged at the right side of the light guide plate 12 for irradiating the five small areas A5 to A9, respectively. The lights irradiated by the light sources 11a0 to 11a9 are incident to the light guide plate 12. The intensity of the lights irradiated by the light sources 11a0 to 11a9 and the irradiating timing thereof are controlled by the backlight controller 6 individually.
Note that, a reflective module (not shown) can be arranged around each of the light sources 11a0 to 11a9 so that the reflective module reflects the lights irradiated toward directions different from the light guide plate 12 into the light guide plate 12.
It is preferable that the prism sheet 14 is arranged only above the diffusion pattern 12a between the light guide plate 12 and the liquid crystal panel 1, and not arranged at other places.
When the lights are irradiated by the light sources 11a0 to 11a9 toward the light guide plate 12, the lights are totally reflected in a part where the diffusion pattern 12a is not formed in the light guide plate 12 and the lights are taken out from a part where the diffusion pattern 12a is formed. That is, the part where the diffusion pattern 12a is formed is a light output face. Then, the traveling direction of the lights is set to a direction vertical to the liquid crystal panel 1 by the prism sheet 14, and the lights reach the first area in the liquid crystal panel 1. Note that, although only the prism sheet 14 whose ridge lines are orthogonal to the incident direction of the light source is shown, it is general to arrange prism sheets whose ridge lines are parallel to the incident direction of the light source, and both of prism sheets can be arranged.
Because the prism work 12b is formed whole of the back face of the light guide plate 12, straight proceeding property from the light source is kept by recursive reflection of the light guide plate 12. By controlling the light sources 11a0 to 11a9 individually by the backlight controller 6, the intensity of the lights reaching each of the small areas A0 to A9 in the first area and the irradiating timing can be controlled individually.
On the other hand, as shown in
As shown in
It is preferable that the prism sheets 15 are arranged only above the reflective faces 13a between the light guide plate 12 and the reflective plate 13, and not arranged at the other places.
When the lights are irradiated by the light sources 11b0 to 11b9 toward the reflective plate 13, the lights proceeds in air above the reflective plate 13 and are reflected by the reflective face 13a toward the liquid crystal panel 1. Then, the traveling direction of the lights is set to the direction orthogonal to the liquid crystal panel 1 by the prism sheets 15, and the lights reach the second area in the liquid crystal panel 1. Because partitions 13c are formed, the intensity of the lights reaching each of the small areas B0 to B9 in the second area and the irradiating timing can be controlled individually by controlling the light sources 11b0 to 11b9 individually by the backlight controller 6.
Note that, it is preferable that the partitions 13c are formed so that a part of light irradiated by one of the light sources 11b0 to 11b9 reaches not only the corresponding one small area in the second area, but also at least one neighboring small area. For example, it is preferable that a part of the light irradiated by the light source 11b2 reaches not only the small area B2 but also the small areas B1 and B3. By such a manner, it is possible to prevent ununiformity from occurring at the boundary between the small areas when two or more neighboring small areas are desired to be irradiated at the same intensity.
Furthermore, although the reflective faces 13a of the reflective plate 13 can be flat, it is preferable that the surface of the reflective face 13a is curved so that the intensity of the light, which is irradiated by each of the light sources 11b0 to 11b9 and is reaching each of the small areal B0 to B9 of the liquid crystal panel 1, becomes uniform.
As stated above, in the first embodiment, the lights are irradiated on the first area of the liquid crystal panel 1 by using the light guide plate 12 and irradiated on the second area by using the reflective plate 13 arranged under the light guide plate 12. Therefore, only one light guide plate 12 is needed. Furthermore, it is preferable that the prism sheet 14 is arranged only above the diffusion pattern 12a and that the prism sheets 15 are arranged above the reflective faces 13a of the reflective plate 13. As a result, the backlight module can be implemented by simplified structure, thereby reducing the manufacturing cost of the LCD.
Note that, when there is a space under the flat face 13b of the reflective plate 13, the LCD becomes small and thin by arranging at least a part of the image processing circuit 2, the timing controller 3, the gate driver 4, the source driver 5 and the backlight controller 6 of
(Second Embodiment)
In the above described first embodiment, the light sources 11 are arranged at the left side and the right side of the liquid crystal panel 1. On the other hand, in a second embodiment which will be explained below, the light sources 11 are arranged at the under side of the liquid crystal panel 1. Hereinafter, differences from the first embodiment will be mainly explained.
The lights irradiated by the light sources 11c0 to 11c5 are taken out from the diffusion pattern 12a of the light guide plate 12 to reach the small areas C0 to C5 through the prism sheet 14, respectively. On the other hand, the lights irradiated by the light sources 11d0 to 11d5 are reflected by the reflective faces 13a of the reflective plate 13 toward the liquid crystal panel 1 to reach the small areas D0 to D5 through the prism sheet 15, respectively. By controlling the light sources 11c0 to 11c5 and 11d0 to 11d5 individually by the backlight controller 6, the intensity of the lights reaching each of the small areas C0 to C5 and D0 to D5 and the irradiating timing can be controlled individually.
As stated above, in the second embodiment, light sources 11 are arranged only at the under side of the liquid crystal panel 1. Therefore, the structure of the backlight module becomes further simplified, thereby manufacturing the LCD with small space and low cost.
Note that, the arrangement of the light sources is not limited to
Furthermore, it is enough that the liquid crystal panel 1 is divided into at least one first small area and one second small area. When the liquid crystal panel 1 is divided into a plurality of first small areas and second small areas, the prism work 12b is formed whole of the back surface of the light guide plate 12 and the light guide plate 12 has a plurality of light output faces divided by increasing direct proceeding property of the lights, and the reflective plate 13 has a plurality of reflective faces 13c divided by the partitions 13c. Here, the light output face has the prism work 12b and increases the straight proceeding property, and the reflective faces 13c are divided by the partitions 13c. Contrarily, when the liquid crystal panel 1 is divided in to one first small area and one second small area, the prism work 12b and the partition 13c are not needed, and one light output face and one reflective face are formed.
(Third Embodiment)
In the above described first and the second embodiments, the intensity of the lights reaching each of the small areas becomes uniform by the shape of the reflective face 13a of the reflective plate 13. On the other hand, in a third embodiment which will be described below, the intensity of the lights becomes uniform by coating the reflective faces 13a.
When the LCD is thinned, freedom degree of the shape of the reflective face 13a becomes small. Therefore, it is not always possible to uniform the intensity of the lights reaching each of the small areas. Accordingly, at least a part of the reflective faces 13a is coated whitely, for example. The lights reflected on the coated part are diffused, and the intensity of the lights reflected to the liquid crystal panel 1 becomes large. Hereinafter, a ratio of the intensity of the lights reflected to the liquid crystal panel 1 at a point on the reflective face 13a to that irradiated to the point is defined as a diffusion reflection ratio.
Accordingly, as shown in
By such a manner, although the intensity of the light irradiated by the light source 11 is small at positions where the distance “d” from the light source 11 is large, the diffusion reflection ratio becomes large. As a result, the liquid crystal panel 1 can be irradiated with the uniform light intensity. This manner can be applicable regardless of the arrangement of the light sources 11.
As stated above, in the third embodiment, at least a part of the reflective faces 13a of the reflective plate 13 is coated to improve the diffusion reflection ratio. Therefore, even if the freedom degree of the shape of the reflective face 13a is small, the liquid crystal panel 1 can be irradiated with the uniform light intensity.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the methods and systems described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fail within the scope and spirit of the inventions.
Morino, Takeshi, Shiratsuchi, Masataka, Isogawa, Kenzo, Momonoi, Yoshiharu, Ohwaki, Kazuyasu
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